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lacunr
is an R package for calculating 3D lacunarity
from voxel data. It is designed to be used with LiDAR point clouds to
measure the heterogeneity or “gappiness” of 3-dimensional structures
such as forest stands. It provides fast C++ functions to efficiently
convert point cloud data to voxels and calculate lacunarity using
different variants of Allain & Cloitre’s well-known gliding-box
algorithm.
You can install lacunr
from CRAN with:
install.packages("lacunr")
Or you can install the development version of lacunr
from GitHub with:
# install.packages("devtools")
::install_github("ElliottSmeds/lacunr") devtools
The standard workflow for lacunr
is fairly simple:
voxelize()
bounding_box()
lacunarity()
library(lacunr)
# create a data.frame of simulated point cloud data
<- data.frame(X = rnorm(1000, 10), Y = rnorm(1000, 50), Z = rnorm(1000, 25))
pc # convert to voxels of size 0.5
<- voxelize(pc, edge_length = c(0.5, 0.5, 0.5))
vox # generate binary map
<- bounding_box(vox)
box # calculate lacunarity curve
<- lacunarity(box) lac_curve
lidR
The lidr
package offers a robust suite of tools for processing LiDAR data.
While lacunr
does not require lidR
as a
dependency, it is assumed that most users will be working with point
cloud data imported using lidR
, and the package is designed
to mesh well with lidR
’s data objects. The following tips
will help make combining these packages as seamless as possible.
LAS
objectsUsers should take special care when using a lidR
LAS
object as input for the voxelize()
function. Since LAS
is an S4 class, it is important to
extract the point cloud data from the LAS
object using
@data
, otherwise voxelize()
will throw an
error:
library(lidR)
# read in LAS point cloud file
<- readLAS("<file.las>")
las # voxelize the LAS point cloud, taking care to input the correct S4 slot
<- voxelize(las@data, edge_length = c(0.5, 0.5, 0.5)) vox
lidR
lidR
offers its own extremely versatile voxelization
function, voxel_metrics()
.
This provides a useful alternative to voxelize()
, although
it is important to note that both functions utilize different algorithms
and will not produce identical results (see the following section for
more details).
voxel_metrics()
returns a lasmetrics3d
object. lacunr
’s bounding_box()
function can
accept this as an input, but it also requires that it contain a column
named N
, recording the number of points in each voxel. This
column can be generated by voxel_metrics()
using the
following:
# read in LAS point cloud file
<- readLAS("<file.las>")
las # voxelize at 1m resolution, creating a column N containing the number of points
<- voxel_metrics(las, ~list(N = length(Z)), res = 1)
vox # convert to array
<- bounding_box(vox) box
voxelize()
vs lidR::voxel_metrics()
voxelize()
is adapted from the function
voxels()
, originally written by J. Antonio Guzmán Q. for
the package rTLS
. It is
intended as a complement rather than a replacement for
lidR
’s more elaborate voxel_metrics()
. Each
function has a different underlying algorithm and will produce distinct
results from the same input data. The chief advantages of
voxelize()
over voxel_metrics()
are:
voxel_metrics()
permits at most two
dimensions.voxel_metrics()
. This is due to differences in how each
function aligns the point cloud data within the voxel grid.These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.